Effect of Functional Groups in Lipid Molecules on the Stability of Nanostructured Lipid Carriers: Experimental and Computational Investigations.

Lipid nanoparticles have been used as drug carriers for decades. Many lipid types have been screened for both solid lipid nanoparticles and nanostructured lipid carriers (NLCs). Specifically, for NLCs that are composed of lipids in the solid form mixed with lipids in the liquid form, compatibility of lipid combination and phase behavior play a significant role in the NLC quality. In this study, stearic acid (STA) and cetyl palmitate (CTP) were used as solid lipids, and oleic acid (OLA), isopropyl palmitate (IPP), and caprylic/capric triglycerides were used as liquid lipids. NLCs were prepared at solid:liquid ratios of 50:50, 70:30, and 90:10, respectively. The characteristics and stability of the prepared NLCs were investigated. Laboratory results showed that the solid lipid had a greater influence on the particle size than the liquid lipid. Meanwhile, cetyl palmitate, an ester compound, provides higher NLC stability compared to stearic acid, a carboxylic acid compound. A MARTINI-based coarse-grained molecular dynamics simulation was used to simulate the lipid droplet in water. The distribution of lipid molecules in the droplet was characterized by the polar group density distribution. Different spatial arrangements of the lipid headgroup and lipid molecules, when CTP or STA was used as solid lipids, might contribute to the different stabilities of prepared NLCs. The understanding of mixed lipid systems via simulations will be a significant tool for screening the type of lipids for drug carriers and other pharmaceutical applications.

Constructing Ni-Pt Bimetallic Catalysts for Catalytic Hydrogenation and Rearrangement of Furfural into Cyclopentanone with Insight in H/D Exchange by D2O Labeling.

Developing a metallic catalyst for converting furfural (FAL) to highly valuable products such as cyclopentanone (CPO) is important for fine chemical synthesis by the efficient utilization of biomass resources. The presence of diverse unsaturated carbon atoms in FAL and the rearrangement of oxygen atoms hinder the production of CPO. We developed an optimal nickel (Ni)-to-platinum (Pt) molar ratio (1:0.007) for a bimetallic Ni-Pt/alumina (Al2O3) catalyst with a low Pt loading via an impregnation method to efficiently catalyze the selective hydrogenation of FAL in an aqueous solution to form CPO. The comprehensive characterizations by X-ray diffraction and X-ray absorption near edge structure analyses elucidated the formation of Ni0/Pt0 and Ni2+/Pt4+ after reduction by H2. The addition of a low amount of the Pt-Ni/Al2O3 catalyst resulted in an alleviation of H2 reduction behavior detected by hydrogen temperature-programmed reduction, accompanied by low H2 desorption ability observed by hydrogen temperature-programmed desorption. The catalytic activity of Ni-Pt/Al2O3 was higher than those of Ni/Al2O3 and Pt/Al2O3 catalysts. The maximum CPO yield was 66% with 93% FAL conversion under the optimized conditions (160 °C, 20 bar of H2 pressure, and 2 h). Isotopic deuterium oxide (D2O) labeling revealed the transfer of deuterium (D) atoms from D2O to the intermediates and products during hydrogenation and rearrangement, which confirmed that water was a medium for rearrangement and the source of hydrogen for the reaction. This study developed an efficient catalyst for the catalytic hydrogenation and ring rearrangement of FAL into CPO.

Effect of Lipid and Oil Compositions on Physicochemical Properties and Photoprotection of Octyl Methoxycinnamate-loaded Nanostructured Lipid Carriers (NLC).

This study aimed to evaluate the effect of solid lipid and oil structures on the physicochemical properties, kinetic release, photostability, and photoprotection of nanostructured lipid carriers (NLC) containing octyl methoxycinnamate (OMC). OMC was used as a model compound since it is an effective sunscreen agent and is widely used in sunscreen products; however, it is unstable after ultraviolet radiation (UVR) exposure. OMC-loaded NLC were prepared from different solid lipids (cetyl palmitate (CP) or tristearin) and oils (caprylic/capric triglyceride, isopropyl myristate or isononyl isononanoate) at a 4:1 ratio. After production, the particle size (z-ave) and polydispersity index (PDI) of OMC-loaded NLC ranged from 190 to 260 nm and were lower than 0.25, respectively, and the zeta potential (ZP) values were higher than |50 mV|. The Fourier transform infrared (FTIR) spectroscopy results indicated no interaction among the components. Data obtained from differential scanning calorimetry (DSC) and X-ray diffraction showed that the incorporation of oil into solid lipids disturbed the crystallinity of the lipid matrix, depending on the structure of the oil molecule. OMC loaded in tristearin-based NLC (OMC-tristearin-NLC) showed higher release of OMC than OMC loaded in CP-based NLC (OMC-CP-NLC). For photostability properties, OMC-CP-NLC prepared from isononyl isononanoate showed the highest stability owing to the less-ordered structure, providing space for accommodation of OMC, whereas the percentage of OMC remaining in tristearin-based NLC was comparable. Therefore, the degree of protection was dependent on the type of solid lipid and oil. As a result, branched-chain fatty acids provided a higher degree of disturbance than linear-chain fatty acid.

Effect of Oil Content on Physiochemical Characteristics of γ-Oryzanol-Loaded Nanostructured Lipid Carriers.

Nanostructured lipid carriers (NLCs) are used as alternative carriers for many different drug delivery administration routes. They are composed of both solid lipid and liquid lipid (oil content) with both influencing their structural properties. Amounts of liquid lipid in NLCs play a role in drug release. Effect of liquid lipid (oil content) on physiochemical characteristics of NLCs related to drug-release requires detailed investigation. Here, many techniques were performed to analyze the physiochemical characteristics of NLCs, especially inside the particles. γ-Oryzanol (GO)-loaded NLCs were prepared at varying solid lipid to liquid lipid ratios. Their physicochemical properties, drug release profiles, and stability studies of prepared NLCs were investigated. Oil contents in NLCs were found to play a significant role in physiochemical characteristics related to drug release and stability, and also influence the efficiency of analytical techniques such as transmission electron microscopy (TEM) and dynamic force microscopy (DFM). Moreover, x-ray diffraction (XRD) and Fourier transform infrared spectroscopy (FTIR) gave information regarding crystallinity inside the NLCs. FTIR showed broad peaks in the range from 1184 cm-1 to 1475 cm-1 while XRD presented a broad curve indicated amorphous forms in NLCs. Orthorhombic lattices (ß' polymorph) were also elucidated by XRD and differential scanning calorimetry (DSC).

Development of γ-Oryzanol Rich Extract from Leum Pua Glutinous Rice Bran Loaded Nanostructured Lipid Carriers for Topical Delivery.

Leum Pua is native Thai glutinous rice that contains antioxidants higher than white rice and other colored rice. One of the major antioxidants in rice brans is γ-oryzanol (GO). In this study, Leum Pua glutinous rice bran was extracted by different solvents. Oleic acid (~40 g/100 g extract), linoleic acid (~30 g/100 g extract), and palmitic acid (~20 g/100 g extract) were found to be major lipid components in the extracts. Methanol extract showed less variety of lipid components compared to the others. However, hexane extract showed the highest percent of γ-oryzanol compared to other solvents. Therefore, the hexane extract was selected to prepare nanostructured lipid carriers (NLC). The prepared NLC had small particles in the size range of 142.9 ± 0.4 nm for extract-loaded NLC and 137.1 ± 0.5 nm for GO-loaded NLC with narrow size distribution (PI < 0.1) in both formulations. The release profile of extract-loaded NLC formulation was slightly higher than GO-loaded NLC formulation. However, they did not follow the Higuchi model because of small amounts of γ-oryzanol loaded in NLC particles.

NanoCluster Itraconazole Formulations Provide a Potential Engineered Drug Particle Approach to Generate Effective Dry Powder Aerosols.

BACKGROUND: Itraconazole (ITZ), a triazole antifungal agent, is a poorly water-soluble drug that is orally administered for treatment of fungal infections such as allergic bronchopulmonary aspergillosis (ABPA) and invasive aspergillosis (IA). ABPA is relatively well controlled but IA can be fatal, especially in immunosuppressed patients. Aerosolized ITZ delivered to the lung may provide a local treatment and prophylaxis against IA at the primary site of infection in the lungs. Variations of the percent fine particle fraction (FPF), the percent emitted dose, and the physical properties of the aerosol (e.g., crystallinity) can confound consistent delivery. METHODS: ITZ NanoClusters were formulated via milling (top-down process) or precipitation (bottom-up process) without using any excipients. Itraconazole formulations (ITZ) were prepared by milling 1 gram of micronized itraconazole in 300 mL of fluid. The suspension was collected at 0.5, 1, and 2 hours milling time. Milled ITZ was compared to ITZ prepared by anti-solvent precipitation and to the stock micronized itraconazole. The aerosolization performance of ITZ formulations was determined using an Andersen Cascade Impactor (ACI). RESULTS: The physicochemical properties and aerosol performance of different ITZ NanoClusters suggested an optimized wet milling was the preferred process compared to precipitation. ITZ NanoClusters prepared by wet milling showed better aerosol performance compared to micronized ITZ as received and ITZ NanoClusters prepared by precipitation. ITZ NanoClusters prepared by precipitation methods also showed an amorphous state, while ITZ milled in 10% EtOH maintained the crystalline character of ITZ throughout a 2 hour milling time. CONCLUSIONS: The aerosol performance of milled ITZ NanoClusters was dramatically improved compared to micronized ITZ as received due to the difference of drug particle structures. ITZ NanoCluster formulations represent a potential engineered drug particle approach for inhalation therapy, providing effective aerosol properties and stability due to the crystalline state of the drug powders.

NanoCluster budesonide formulations enable efficient drug delivery driven by mechanical ventilation.

Agglomerates of budesonide nanoparticles (also known as 'NanoClusters') are fine dry powder aerosols that were hypothesized to enable drug delivery through ventilator circuits. These engineered powders were delivered via a Monodose inhaler or a novel device, entrained through commercial endotracheal tubes, and analyzed by cascade impaction. Inspiration flow rates and other parameters such as inspiration patterns and inspiration volumes were controlled by a ventilator. NanoCluster budesonide (NC-Bud) formulations had a higher efficiency of aerosol delivery compared to micronized budesonide with NC-Bud showing a much higher percent emitted fraction (%EF). Different inspiration patterns (sine, square, and ramp) did not affect the powder performance of NC-Bud when applied through a 5.0 mm endotracheal tube. The aerosolization of NC-Bud also did not change with the inspiration volume (1.5-2.5 L) nor with the inspiration flow rate (20-40 L/min) suggesting fast emptying times for budesonide capsules. The %EF of NC-Bud was higher at 51% relative humidity compared to 82% RH. The novel device and the Monodose showed the same efficiency of drug delivery but the novel device fit directly to a ventilator and endotracheal tubing connections. The new device combined with NanoCluster formulation technology allowed convenient and efficient drug delivery through endotracheal tubes.

Nanocluster budesonide formulations enhance drug delivery through endotracheal tubes.

The pulmonary system is an attractive route for drug delivery because the lungs have a large accessible surface area for treatment. For ventilated patients, an endotracheal tube is required for delivering drugs into the lungs. Such tubes are generally poor conduits for delivering traditional aerosol formulations. Both the formulation and the properties of the endotracheal tube are important effectors of delivery efficiency. In this study, agglomerates of budesonide nanoparticles (NanoClusters) were formulated with or without l-leucine or lactose. Teflon tubing was compared with commercial endotracheal tubes as a conduit for delivering budesonide powders into a cascade impactor. The effects of volumetric flow rate, tube size, and humidity were also investigated. NanoCluster budesonide (NC-Bud) formulations had a considerably higher emitted dose and fine particle fraction compared with stock budesonide and the commercial Flexhaler powder when applied through endotracheal tubes. Tubing material did not significantly affect powder performance, but decreasing tubing diameter or increasing volumetric flow rates yielded a smaller mass median aerodynamic diameter for NC-Bud. Engineered NC-Bud powders may dramatically improve drug delivery through endotracheal tubes when using proper ventilator settings.

Nanoparticle agglomerates of fluticasone propionate in combination with albuterol sulfate as dry powder aerosols.

Particle engineering strategies remain at the forefront of aerosol research for localized treatment of lung diseases and represent an alternative for systemic drug therapy. With the hastily growing popularity and complexity of inhalation therapy, there is a rising demand for tailor-made inhalable drug particles capable of affording the most proficient delivery to the lungs and the most advantageous therapeutic outcomes. To address this formulation demand, nanoparticle agglomeration was used to develop aerosols of the asthma therapeutics, fluticasone or albuterol. In addition, a combination aerosol was formed by drying agglomerates of fluticasone nanoparticles in the presence of albuterol in solution. Powders of the single drug nanoparticle agglomerates or of the combined therapeutics possessed desirable aerodynamic properties for inhalation. Powders were efficiently aerosolized (∼75% deposition determined by cascade impaction) with high fine particle fraction and rapid dissolution. Nanoparticle agglomeration offers a unique approach to obtain high performance aerosols from combinations of asthma therapeutics.